US10495793B2ActiveUtilityA1
Systems and methods for lensless image acquisition
Est. expiryFeb 12, 2035(~8.6 yrs left)· nominal 20-yr term from priority
Inventors:Patrick R. Gill
H04N 23/60G02B 5/1871G06T 2207/20056G06T 5/10G02B 5/1814H04N 5/2254G06T 3/0018G06T 5/006H04N 5/23229H04N 23/955G06T 3/047G06T 5/80
66
PatentIndex Score
1
Cited by
19
References
18
Claims
Abstract
Image-sensing devices include odd-symmetry gratings that cast interference patterns over a photodetector array. Grating features offer considerable insensitivity to the wavelength of incident light, and also to the manufactured distance between the grating and the photodetector array. Photographs and other image information can be extracted from interference patterns captured by the photodetector array. Efficient extraction algorithms based on Fourier deconvolution introduce barrel distortion, which can be removed by resampling using correction functions.
Claims
exact text as granted — not AI-modifiedWhat is claimed is:
1. A method of imaging a scene, the method comprising:
storing a deconvolution kernel associated with a point-spread function of a diffraction grating;
passing light from the scene through the diffraction grating to produce a distorted interference pattern;
sampling the distorted interference pattern with a sensor array to obtain a digital sample of the distorted interference pattern;
constructing a distorted image of the scene from the digital sample of the distorted interference pattern and the deconvolution kernel, wherein the distorted image of the scene includes distorted aspects of the scene from which the light passed through the diffraction grating to produce the distorted interference pattern; and
resampling the distorted image of the scene to reduce the distorted aspects of the scene from which the light passed through the diffraction grating to produce the distorted interference pattern;
wherein the resampling of the distorted image includes adjusting the distorted image to compensate for an error representing an actual path from an ideal path of light arriving at the sensor array using a lookup table with values dependent on (i) a thickness h of an optical medium separating the sensor array from the diffraction grating, (ii) a refractive index n of the optical medium, and (iii) a distance r s of the distorted image from an optical axis of the diffraction grating.
2. The method of claim 1 , wherein constructing the distorted image includes deconvolving the digital sample of the distorted interference pattern with the point-spread function to obtain the distorted image.
3. The method of claim 2 , wherein the deconvolving applies Fourier deconvolution.
4. The method of claim 1 , wherein the resampling applies a correction function.
5. The method of claim 1 , wherein the resampling includes interpolation between neighboring values in the digital sample.
6. The method of claim 1 , wherein the scene includes an object a distance d w from the sensor and laterally displaced from the optical axis of the diffraction grating by a displacement r w , and wherein the distance
r
s
=
h
tan
(
sin
-
1
(
1
n
sin
(
tan
-
1
(
r
w
d
w
)
)
)
)
.
7. A method of imaging a scene, the method comprising:
storing a deconvolution kernel associated with a point-spread function of a diffraction grating;
passing light from the scene through the diffraction grating to produce a diffraction pattern;
sampling the diffraction pattern with a sensor array to obtain a digital sample of the diffraction pattern;
constructing a distorted image of the scene from the digital sample; and
resampling the distorted image of the scene to obtain a reduced-distortion image of the scene;
wherein the grating is separated from the sensor array by a separation h, the scene includes an object a distance d w from the sensor and laterally displaced from an optical axis of the sensor by a displacement r w , and wherein resampling the distorted image includes calculating a sensor displacement
r
s
=
h
tan
(
sin
-
1
(
1
n
sin
(
tan
-
1
(
r
w
d
w
)
)
)
)
of a portion of a digital sample representative of the object on the sensor.
8. A system for imaging a scene, the system comprising:
a photodetector array;
a phase grating separated from the photodetector array by an optical medium of a thickness h and a refractive index n, the phase grating to produce a distorted interference pattern from the scene passing through the phase grating;
memory to store a lookup table and a deconvolution function corresponding to a point-spread function of the phase grating;
a sensor array to capture a digital sample of the distorted interference pattern; and
a processor coupled to the sensor array and the memory, the processor to:
deconvolve the digital sample of the distorted interference pattern with the point-spread function to obtain distorted image data; and
resample the distorted image data to obtain a reduced-distortion image of the scene
wherein the resampling of the distorted image includes adjusting the distorted image to compensate for an error representing an actual path from an idea path of light arriving at the sensor array using the lookup table with values dependent on (i) the thickness h of the optical medium separating the sensor array from the phase grating, (ii) the refractive index n of the optical medium, and (iii) and a distance r s of the distorted image from an optical axis of the phase grating.
9. The system of claim 8 , wherein the deconvolving of the digital sample applies Fourier deconvolution.
10. The system of claim 8 , wherein the processor, in resampling the distorted image data, interpolates between neighboring values in the distorted image data.
11. The system of claim 8 , wherein the array has an array area, the system further comprising an aperture having an aperture area less than the array area.
12. The system of claim 11 , wherein the aperture is disposed between the grating and the array.
13. The system of claim 11 , wherein the aperture is integrated with the grating.
14. The system of claim 8 , wherein the processor is integrated with the array.
15. The system of claim 8 , wherein the phase grating defines a transverse plane and includes odd-symmetry boundaries on the transverse plane and extending radially, each boundary defined by adjacent first and second features of odd symmetry located respectively to each side of that boundary.
16. The system of claim 15 , wherein each odd-symmetry boundary induces, at position on the array underlying that boundary, for light in a wavelength band of interest incident the grating and normal to the transverse plane of the grating, a half-wavelength shift with respect to each other for the light passing through the adjacent first and second features.
17. The system of claim 8 , wherein the scene includes an object a distance d w from the sensor and laterally displaced from the optical axis of the phase grating by a displacement r w , and wherein the distance
r
s
=
h
tan
(
sin
-
1
(
1
n
sin
(
tan
-
1
(
r
w
d
w
)
)
)
)
.
18. A system for imaging a scene, the system comprising:
a photodetector array;
a phase grating overlying the photodetector array, the phase grating to produce a distorted interference pattern from the scene passing through the phase grating;
memory to store a deconvolution function corresponding to a point-spread function of the phase grating;
a sensor array to capture a digital sample of the distorted interference pattern; and
a processor coupled to the sensor array and the memory, the processor to:
deconvolve the digital sample of the distorted interference pattern with the point-spread function to obtain distorted image data; and
resample the distorted image data to obtain a reduced-distortion image of the scene;
wherein the grating is separated from the array by a separation h, the scene includes an object a distance d w from the sensor and laterally displaced from an optical axis of the sensor by a displacement r w , and wherein resampling the distorted image data includes calculating a sensor displacement
r
s
=
h
tan
(
sin
-
1
(
1
n
sin
(
tan
-
1
(
r
w
d
w
)
)
)
)
of a portion of a digital sample representative of the object on the sensor.Cited by (0)
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